Devices and Methods for Reducing Battery Defects

ABSTRACT

Solid-state battery structures and methods of manufacturing solid-state batteries are disclosed. More particularly, embodiments relate to solid-state batteries having one or more subdivided electrode layers. Other embodiments are also described and claimed.

This application is a divisional of U.S. patent application Ser. No.14/722,077 filed on May 26, 2015, which claims the benefit of U.S.Provisional Patent Application No. 62/003,509, filed May 27, 2014, andU.S. Provisional Patent Application No. 62/165,105, filed May 21, 2015,and this application hereby incorporates herein by reference thoseprovisional patent applications.

TECHNICAL FIELD

Embodiments relate to electrochemical devices and methods ofmanufacturing electrochemical devices. More particularly, embodimentsrelate to thin film electrochemical devices, including batteries, whichincorporate one or more subdivided electrode layers.

BACKGROUND

Solid-state batteries, such as thin-film batteries (TFBs), are known toprovide better form factors, cycle life, power capability, and safety,as compared to conventional battery technologies. However, solid-statebattery structures and manufacturing methods require furtheroptimization to reduce fabrication costs and improve performance.

Referring to FIG. 1, an electrochemical cell 100, which may beincorporated in a solid-state battery, includes a first electrode, e.g.,an anode layer 102, separated from a second electrode, e.g., a cathodelayer 104, by an electrolyte layer 106. During manufacturing of thesolid-state battery, a defect 108 may occur in the electrolyte layer 106that causes internal short-circuiting between the electrodes. Moreparticularly, the defect 108, which may be a crack or pinhole extendingbetween the anode layer 102 and the cathode layer 104, can cause aninternal, electronic leak through the electrolyte layer 106 duringfabrication or operation of the battery. For example, an anode leak 110may propagate through the defect 108 into the cathode layer 104, causinga chemical reaction 112 that chemically reduces or over discharges someor all of the cathode layer 104 and eventually affects the entirecathode layer 104 to degrade battery performance and/or disable thebattery.

SUMMARY

Embodiments of solid-state battery structures are disclosed. In anembodiment, an electrochemical cell includes a cathode layer having agroup of two or more cathode subregions that are electrically separatedby one or more gaps, and an electrolyte layer between the cathodesubregions and an anode layer. The cathode subregions may beelectrically connected to a common cathode current collector. Thecathode current collector may have a continuous layer structure suchthat the cathode subregions are electrically connected to each otherthrough the continuous layer structure of the cathode current collector.In an embodiment, a combined projected surface area of the cathodesubregions is at least 80 percent of a total projected surface area ofwhat would be a “filled” or solid cathode layer, i.e., one in which thegaps between the cathode sub-regions are filled with cathode material.In an embodiment, the gaps are at least partially filled by a dielectricmaterial, e.g., a dielectric gas. An anode current collector may belocated over the anode layer. An insulating layer, such as one that isinert to lithium, may be located over the anode layer.

The one or more gaps may also be partially filled by at least one of theelectrolyte layer or the anode layer. For example, the cathodesubregions may include respective sidewalls that are separated by thegaps and the anode layer may have a continuous layer structure thatcovers the sidewalls of the cathode subregions, and thus, is disposed inthe gaps between the sidewalls. In addition to separating the sidewalls,the gaps may separate a portion of the anode layer between the sidewallsfrom the anode current collector that extends over plateaus of thecathode subregions.

In an embodiment, the anode layer includes several anode subregionsseparated by the one or more gaps. For example, an electrochemical cellmay include an anode layer having a discontinuous layer structure. Thatis, the anode layer may include several anode subregions separated byone or more gaps. An electrolyte layer may be disposed between severalanode subregions and a cathode layer. In an embodiment, an anode currentcollector extends over the anode subregions and includes a continuouslayer structure such that the anode subregions are electricallyconnected to each other through the continuous layer structure of theanode current collector. A combined projected surface area of the anodesubregions may be less than 25 percent of a total projected surface areaof what would be described as a “filled” or solid anode layer.

In an embodiment, an electrochemical device includes two electrochemicalcells that include respective cathode layers covered by respective anodelayers. The cathode layers may have several cathode subregions separatedby a gap. The cathode subregions may be electrically connected to acommon cathode current collector, i.e., the cathode subregions of eachcell may be electrically connected to each other through the respectivecathode current collector. In an embodiment, the cells are stacked suchthat the anode layer of one cell is physically connected to the anodelayer of the other cell.

A tab insertion space may be disposed between the cathode currentcollectors of the stacked cells, and an anode current collector tab maybe disposed in the tab insertion space. The anode layers of the cellsmay include continuous layer structures that separate the tab insertionspace from respective cathode current collectors. Thus, the anodecurrent collector tab disposed in the tab insertion space may beconnected to the anode layers between the cathode current collectors. Inan embodiment, an insulating layer, such as an insulating layer that isalso inert to lithium, may be disposed between the cathode layers andphysically connected to the anode layers.

In an embodiment, an electrochemical cell includes an anode currentcollector having a continuous layer structure. An anode layer may besubdivided into anode subregions that are electrically connected to eachother through the continuous layer structure of the anode currentcollector. An electrolyte layer may be disposed between the anodesubregions and a cathode layer. In an embodiment, the anode subregionsare separated by a gap that extends between the anode current collectorand the electrolyte layer. The gap may be at least partially filled by adielectric material, e.g., a dielectric gas. The cell may include acathode current collector having a continuous layer structure that iselectrically connected to the cathode layer. In an embodiment, acombined projected surface area of the anode subregions is less than 25percent of a total projected surface area of the anode layer.

In an embodiment, the cathode layer of the cell includes several cathodesubregions, and at least two of the anode subregions are disposed overeach cathode subregion. The cathode subregions may be separated fromeach other by a gap that extends between the anode current collector andthe cathode current collector. The gap may be at least partially filledby a dielectric material, e.g., a dielectric gas. Furthermore, thecathode subregions may be electrically connected to each other throughthe continuous layer structure of the cathode current collector. Acombined projected surface area of the cathode subregions may be atleast 80 percent of a total projected surface area of the cathode layer.

In an embodiment, an electrochemical device includes a stack ofelectrochemical cells having respective anode layers. The anode layersmay include several anode subregions and the cells may includerespective electrolyte layers between the anode subregions and arespective cathode layer. In an embodiment, an anode current collectorhaving a continuous layer structure is disposed between the cathodelayers and is physically connected to the anode subregions of thestacked cells. Thus, the anode subregions are electrically connected toeach other through the continuous layer structure of the anode currentcollector. The cells may also include respective cathode currentcollectors that are electrically connected to the cathode layers of therespective cells. In an embodiment, a combined projected surface area ofthe anode subregions of each cell is less than 25 percent of a totalprojected surface area of the anode layers of each cell.

The above summary does not include an exhaustive list of all aspects ofthe present invention. It is contemplated that the invention includesall systems and methods that can be practiced from all suitablecombinations of the various aspects summarized above, as well as thosedisclosed in the Detailed Description below and particularly pointed outin the claims filed with the application. Such combinations haveparticular advantages not specifically recited in the above summary.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a side view of an electrochemical cell having a defect in anelectrolyte layer.

FIG. 2 is a plan view of an electrochemical cell having a subdividedcathode layer in accordance with an embodiment.

FIG. 3 is a cross-sectional view, taken about line A-A of FIG. 2, of anelectrochemical cell having a subdivided cathode layer in accordancewith an embodiment.

FIGS. 4A-4B are cross-sectional views, taken about line A-A of FIG. 2,of an electrochemical cell having a defect in an electrolyte layer overa subdivided cathode layer in accordance with an embodiment.

FIG. 5 is a plan view of an electrochemical cell having a neutralizedcathode subregion in accordance with an embodiment.

FIG. 6 is a side view of an electrochemical cell having a subdividedcathode layer in accordance with an embodiment.

FIG. 7 is a plan view of an electrochemical cell having a subdividedcathode layer and an anode current collector tab in accordance with anembodiment.

FIGS. 8A-8B are cross-sectional views of an electrochemical devicehaving a defect in an electrolyte layer over a subdivided cathode layerin accordance with an embodiment.

FIG. 9 is a cross-sectional view of an electrochemical device having anintermediate layer between subdivided cathode layers in accordance withan embodiment.

FIG. 10 is a plan view of an electrochemical cell having a subdividedanode layer in accordance with an embodiment.

FIG. 11 is a cross-sectional view, taken about line C-C of FIG. 10, ofan electrochemical cell having a subdivided anode layer in accordancewith an embodiment.

FIG. 12 is a cross-sectional view, taken about line C-C of FIG. 10, ofan electrochemical cell having a defect in an electrolyte layer under asubdivided anode layer in accordance with an embodiment.

FIGS. 13A-13B are cross-sectional views, taken about line C-C of FIG.10, of an electrochemical cell having a defect in an electrolyte layerunder a subdivided anode layer in accordance with an embodiment.

FIG. 14 is a side view of an electrochemical device having an anodecurrent collector between subdivided anode layers in accordance with anembodiment.

FIG. 15 is a plan view of an electrochemical cell having a subdividedanode layer over a subdivided cathode layer in accordance with anembodiment.

FIG. 16 is a cross-sectional view, taken about line D-D of FIG. 15, ofan electrochemical cell having a subdivided anode layer over asubdivided cathode layer in accordance with an embodiment.

FIG. 17 is a flowchart illustrating a method for isolating a cathodelayer from an anode leak in accordance with an embodiment.

FIG. 18 is a side view of an electrochemical cell during a defectdetection operation in accordance with an embodiment.

FIG. 19 is a side view of a precursor cell having a defect in anelectrolyte layer in accordance with an embodiment.

FIG. 20 is a side view of an electrochemical cell having a backfilledelectrolyte layer in accordance with an embodiment.

FIG. 21 is a side view of an electrochemical cell having a defect in anelectrolyte layer in accordance with an embodiment.

FIGS. 22A-22C are side views of an electrochemical cell having a cathodelayer isolated from an anode leak in accordance with an embodiment.

DETAILED DESCRIPTION

Embodiments describe structures and manufacturing methods forsolid-state batteries, such as thin-film batteries. However, while someembodiments are described with specific regard to manufacturingprocesses or structures for integration within a solid-state battery,the embodiments are not so limited, and certain embodiments may also beapplicable to other uses. For example, one or more of the embodimentsdescribed below may be used to manufacture other layered elements, suchas silicon-based solar cells.

In various embodiments, description is made with reference to thefigures. However, certain embodiments may be practiced without one ormore of these specific details, or in combination with other knownmethods and configurations. In the following description, numerousspecific details are set forth, such as specific configurations,dimensions, and processes, in order to provide a thorough understandingof the embodiments. In other instances, well-known processes andmanufacturing techniques have not been described in particular detail inorder to not unnecessarily obscure the description. Reference throughoutthis specification to “one embodiment,” “an embodiment,” or the like,means that a particular feature, structure, configuration, orcharacteristic described is included in at least one embodiment. Thus,the appearance of the phrase “one embodiment,” “an embodiment,” or thelike, in various places throughout this specification are notnecessarily referring to the same embodiment. Furthermore, theparticular features, structures, configurations, or characteristics maybe combined in any suitable manner in one or more embodiments.

In an aspect, an electrochemical cell may include several layers, suchas an electrolyte layer between an anode layer and a cathode layer. Eachof the layers of the electrochemical cell may be formed in a subdividedmanner. For instance, one or more of the electrode layers, i.e., theanode layer or the cathode layer, may be patterned to remove gaps as pera pattern, leaving essentially islands making up the subdivided layer.Other methods for producing a “layer” of anode or cathode islands arepossible.

In an aspect, an electrochemical cell having a cathode layer subdividedinto cathode subregions is provided. For example, the cathode layer maybe subdivided into several rectangular subregions separated by gapsbetween the subregions. Thus, each subregion may be isolated from theothers, and accordingly, an anode leak that chemically reacts within onecathode subregion will not propagate to or affect the other cathodesubregions. Furthermore, the gaps may also serve to provide separationsbetween anode layer regions that are disposed over the cathodesubregions, to limit the anode material that will leak into the cathodesubregions, before an open circuit forms between a defect in theelectrolyte layer and an anode current collector. In an embodiment, thecathode subregions may be electrically connected and physically coupledto a common, or shared, cathode current collector. Thus, the cathodesubregions may be electrically connected to each other through thecathode current collector. For instance, the cathode subregions may bedirectly connected to the common cathode current collector, or one ormore intermediate layers, such as a barrier film layer, may couple thecathode subregions with the common cathode current collector.Accordingly, fabrication yield may be increased and the electrochemicalcell may be more resistant to degradation caused by anode leaks.

In an aspect, an electrochemical cell having an anode layer subdividedinto anode subregions is provided. For example, the anode layer may besubdivided into several rectangular subregions separated by one or moregaps between the subregions. In another embodiment, a subdivided anodelayer having patterned anode islands may be disposed over a subdividedcathode layer. Thus, one or more anode subregions may be located overone cathode subregion. In any case, the total projected surface area ofthe anode subregions may occupy a fraction of the total projectedsurface area of what would be the “filled” or solid anode layer.Accordingly, the probability of a defect in an electrolyte layer beingadjacent to a particular anode subregion is reduced, and even if thedefect does contact an anode subregion, a resulting anode leak may drainone anode subregion (thereby essentially removing that sub-region fromoperation) but not the other anode subregions. Furthermore, as theisolated anode subregion leaks, one or more gaps may form between theportion of the electrolyte layer that is adjacent to that anodesubregion and an anode current collector; this helps reduce thelikelihood of electrical discharge occurring in neighboring anodesubregions (through the anode current collector and the defect).Accordingly, fabrication yield may be increased and the electrochemicalcell may be more resistant to degradation caused by anode leaks.

In an aspect, an electrochemical cell having a repaired defect in anelectrolyte layer is provided. More particularly, the electrochemicalcell may be modified in a precursor state or in an assembled state toreduce the likelihood of an anode leak that could degrade the cathodelayer. A repair may include filling and/or backfilling a portion of theelectrolyte layer that includes the defect. A repair may includeremoving that portion of the anode layer that lies over the defect, andaccordingly, the anode layer cannot leak through the defect into thecathode layer. A repair may include forming a channel around the defectsuch that even if an anode leak does occur, a first portion of thecathode layer that lies under the defect would be isolated from a secondportion of the cathode layer, and thus, degradation of the cathode layerwould be limited to degradation of the first portion.

Referring to FIG. 2, a plan view of an electrochemical cell having asubdivided cathode layer is shown in accordance with an embodiment. Anelectrochemical cell 200 may include an anode layer 202 over a cathodelayer. Furthermore, the cathode layer may be subdivided into one or morecathode subregions 204, shown with hidden lines in FIG. 2, spaced andpatterned across the electrochemical cell 200 beneath the anode layer202. More particularly, the cathode subregions 204 may be separated fromeach other by one or more gaps 206. For example, one or more gaps 206may surround each cathode subregion 204 to physically isolate thecathode subregion 204 from neighboring cathode subregions 204.

In an embodiment, the cathode layer may include a grid pattern, in whicheach cathode subregion 204 includes a rectangular surface area and isseparated from adjacent cathode subregions 204 by one or more lineargaps 206 traversing the electrochemical cell 200. That is, the cathodelayer may have several cathode subregions 204 and one or more gaps 206arranged like city blocks and streets. The grid pattern and city blockmetaphor may lend itself to fabrication. For example, laser scribing maybe used to remove cathode layer material and form one or more gaps 206between cathode subregions 204 after deposition of the cathode materialover a substrate or after connecting the cathode material to a cathodecurrent collector. Alternatively, shadow masking may be used to formcathode subregions 204 separated by masked regions that become theunfilled one or more gaps 206. However, other cathode layer patterns maybe used. For example, the one or more gaps 206 may be laser scribed inany shape to form isolated cathode subregions 204 that are, e.g.,polygonal, conic sections, elliptical, etc., islands. The cathodesubregions 204 may have a same or different shape as compared to othercathode subregions 204 in the cathode layer.

Regardless of the shape of the cathode subregions 204, the cathode layermay include a total projected surface area within an electrochemicalcell perimeter 208 when viewed from above, which includes a combinedsurface area of each cathode subregion 204 and a combined surface areaof each gap 206. For example, each cathode subregion 204 may have aprojected area of a square profile with equal sides. Furthermore, eachgap 206 may be formed by ablating through the cathode layer with a laserbeam to create a grid of trenches with equal widths, i.e., trenchesdevoid of cathode material. Thus, a total projected surface area of thecathode layer within an electrochemical cell perimeter 208 may includeall of the square projected surface areas as well as the projectedsurface area within the one or more gaps. In an embodiment, a patternedcathode area utilization, i.e., a ratio of the combined individualcathode subregion projected surface areas to the total projected surfacearea of the cathode layer, may be greater than 75%, with an errorpercentage of 2-5%. For example, the patterned cathode area utilizationmay be at least 80%, with an error percentage of 2-5%. In an embodiment,a grid pattern has square cathode subregions 204 with sides of 100micron separated by one or more 10 micron gaps. Thus, the patternedcathode area utilization may be expected to be 83%. Narrowing the one ormore gaps 206 or enlarging the cathode subregions 204 can increase thepatterned cathode area utilization.

Referring to FIG. 3, a cross-sectional view, taken about line A-A ofFIG. 2, of an electrochemical cell having a subdivided cathode layer isshown in accordance with an embodiment. In an embodiment, theelectrochemical cell 200 may include an electrolyte layer 302 betweenthe anode layer 202 and the cathode layer 304, and more particularly,between the anode layer 202 and one or more cathode subregions 204.Furthermore, a barrier film layer 306 may optionally be between thecathode layer and a cathode current collector 308. In an embodiment,cathode current collector 308 may have a continuous layer structure,e.g., a continuous sheet or film, extending under the one or morecathode subregions 204. As described above, each of the cathodesubregions 204 may be separated by one or more gaps 206, which defines aspace between the cathode subregions 204 within the cathode layer 304.Thus, the cathode subregions 204 may be electrically connected to eachother through the continuous layer structure of cathode currentcollector 308.

A continuous layer structure as used throughout this specification maybe, but need not be, a completely filled layer. That is, a continuouslayer structure may include one or more local discontinuities, such asholes, gaps, voids, etc. through a thickness of the layer, making thelayer physically discontinuous, but the layer may nonetheless beelectrically continuous in that an electrical potential at one locationon the continuous layer structure may be essentially equal to anelectrical potential at any other location on the continuous layerstructure. Likewise, a continuous layer structure may be physicallycontinuous, having no discontinuities along a layer surface, but maynonetheless be electrically discontinuous, e.g., as in the case of aninsulating layer with different electrical potentials at differentlocations along the surface. Thus, a continuous layer structure may beone or more of physically continuous and/or electrically continuous.

The patterned cathode material of the cathode layer 304, i.e., thecathode subregions 204, may, for example, include LiCoO₂, LiMn₂O₄,LiMnO₂, LiNiO₂, LiFePO₄, LiVO₂, or any mixture or chemical derivativethereof. The electrolyte layer 302 may facilitate ion transfer betweenthe cathode subregions 204 and the anode layer 202. Accordingly, theelectrolyte layer 302 may be a solid electrolyte, which may not containany liquid components and may not require any binder or separatormaterials compounded into a solid thin film. For example, theelectrolyte layer 302 may include lithium phosphorous oxynitride (LiPON)or other solid state thin-film electrolytes such as LiAlF₄, Li₃PO₄ dopedLi₄SiS₄. The anode layer 202 may, for example, include lithium, lithiumalloys, metals that can form solid solutions or chemical compounds withlithium, or a so-called lithium-ion compound that may be used as anegative anode material in lithium-based batteries, such as Li₄Ti₅O₁₂.

In an embodiment, the cathode layer subregions 204 may be electricallyconnected with a cathode current collector 308, which may be anelectrically conductive layer or a tab. Similarly, the anode layer 202may be electrically connected with an anode current collector 310, whichmay be an electrically conductive layer or a tab. Optionally, one ormore intermediate layers may be disposed between the patterned cathodematerial of the cathode layer 304 or the anode layer 202 and arespective current collector. For example, a barrier film layer 306 mayseparate the cathode subregions 204 from the cathode current collector308. For example, the barrier film layer 306 may be in direct physicalcontact with the cathode subregions 204 and the cathode currentcollector 308. The barrier film layer 306 may reduce the likelihood ofcontaminants and/or ions from diffusing between the cathode currentcollector 308 and the cathode subregions 204. Thus, the barrier filmlayer 306 may include materials that are poor conductors of ions, suchas borides, carbides, diamond, diamond-like carbon, silicides, nitrides,phosphides, oxides, fluorides, chlorides, bromides, iodides, andcompounds thereof. Alternatively, an additional intermediate layer, suchas a substrate layer may be disposed between the cathode layer 304 andthe cathode current collector 308. The substrate layer may, for example,provide electrical connectivity between the cathode subregions 204 andthe cathode current collector 308 and may also provide structuralsupport, e.g., rigidity, to the electrochemical cell 200. Accordingly,the substrate layer may include a metal foil or another electricallyconductive layer.

In some instances, the electrochemically active layers of the cell maybe formed on one side of the substrate layer, e.g., using materialdeposition techniques such as physical vapor deposition, and the cathodecurrent collector 308 may be formed separately and physically coupled toanother side of the substrate layer. In other instances, theelectrochemically active layers of the cell may be formed on thesubstrate layer, and then the electrochemically active layers may beremoved from the substrate layer and physically coupled to theseparately formed cathode current collector 308. In still otherinstances, the electrochemically active layers of the cell may beformed, e.g., physical vapor deposited, directly on the cathode currentcollector 308. Thus, there are many different ways to create anelectrochemical cell 200 having several electrochemically active layers.

In an embodiment, the one or more gaps 206 within the patterned cathodelayer 304 are at least partially filled by a dielectric 312. Moreparticularly, sidewalls 314 of respective cathode subregions 204 may beseparated by a dielectric fluid or solid, such as a dielectric gas,e.g., an inert gas. Furthermore, multiple dielectrics or other materialsmay occupy the one or more gaps 206. For example, the electrolyte layer302 and/or the anode layer 202 may be deposited over the sidewalls 314and the barrier film layer 306 to at least partially fill the one ormore gaps 206 between the cathode subregions 204 of the patternedcathode layer 304. The anode layer 202 and/or electrolyte layer 302 maybe deposited in a continuous layer over the cathode subregions 204,thereby forming a continuous covering across adjacent cathode subregions204. That is, anode layer 202 and/or electrolyte layer 302 may have acontinuous layer structure, e.g., a sheet or film structure. Thecontinuous covering may both above cathode subregions 204, e.g., betweencathode subregions 204 and anode current collector 310, as well aslaterally between cathode subregions 204, e.g., disposed between and/orcovering sidewalls 314 of adjacent cathode subregions 204. Furthermore,since one or more of anode layer 202 or electrolyte layer 302 may bedisposed as a continuous layer deposited over cathode subregions 204 andat least partially filling gaps 206, apposing surfaces of the depositedlayers may face each other. This is shown in FIG. 3 in which laterallyfacing surfaces of anode layer 202 face each other across dielectric312, e.g., a dielectric gas. Similarly, the continuous layer structureof anode layer 202 may cover the sidewalls such that dielectric 312separates a portion of the anode layer inside the gap 206, e.g., theportion at the bottom of gap 206 directly above barrier film layer 306,from anode current collector 310. In an embodiment, dielectric 312 isabsent, and the facing surfaces of anode layer 202 touch each other,thereby completely filling at least a portion of gap 206 betweenadjacent cathode subregions 204. That is, apposing surfaces of anodelayer 202 may touch along a bottom half of gap 206, completely fillingthe space between cathode subregions 204 in that lower portion, whilethe apposing surfaces of anode layer 202 may be separated by dielectric312 along a top half of gap 206, in the same manner shown across theentire gap 206 in FIG. 3. Thus, the one or more gaps 206 may provide aphysical and electrochemical separation between adjacent cathodesubregions 204. Furthermore, the portions of anode layer 202 overlyingone cathode subregion 204 may be physically separated from anode layer202 overlying an adjacent cathode subregion 204. However, the anodelayer portions overlying the cathode subregions 204 may be sandwichedbetween the cathode subregions 204 and an anode current collector 310.

Referring to FIG. 4A, a cross-sectional view, taken about line A-A ofFIG. 2, of an electrochemical cell having a defect in an electrolytelayer over a subdivided cathode layer is shown in accordance with anembodiment. In an embodiment, the electrolyte layer 302 may include adefect. The defect may include, for example, a void 402 such as anano-crack, a micro-crack, or a pinhole. The void 402 may occur in theelectrolyte layer 302 during cell fabrication or cell operation. Variouscauses for the void 402 include suboptimal morphology or cleanliness ofany of the cathode current collector 308, the barrier film layer 306,the cathode layer 304, or the electrolyte layer 302. Furthermore,external short-circuiting, mechanical abuse, thermal abuse, etc., maygenerate the void 402. In any case, the void 402 can introduce a pathfor an electrical leak between the anode layer 202 and the cathode layer304. That is, an anode leak 404 may occur as the anode layer 202material creeps into a cathode subregion 204 of the cathode layer 304,through the void 402. As the anode material interacts with the cathodematerial, chemical reactions 406 may propagate through the cathodesubregion 204 to create unwanted chemical products that degradeelectrochemical cell function.

Referring to FIG. 4B, a cross-sectional view, taken about line A-A ofFIG. 2, of an electrochemical cell having a defect in an electrolytelayer over a subdivided cathode layer is shown in accordance with anembodiment. As the anode leak 404 persists, chemical reactions 406through the cathode subregion 204 may continue and be accompanied byconcomitant disappearance of the anode layer 202 over the cathodesubregion 204, as shown in this figure. That is, anode layer 202material may physically leak through the void 402 until there is nolonger anode material directly above void 402. Accordingly, portions ofthe anode layer 202 may remain within the one or more gaps 206 betweencathode subregions 204, but there may be an empty space 408 created in aportion of the anode layer 202 that is above the electrolyte layer 302,e.g., between the electrolyte layer 302 and the anode current collector310. Thus, the anode leak 404 may eventually cease, and as a result, thechemical reaction 406 in the cathode subregion 204 may stop.

Referring to FIG. 5, a plan view of an electrochemical cell having aneutralized cathode subregion is shown in accordance with an embodiment.In an embodiment, after the anode layer 202 has leaked into the cathodesubregion 204 through the void 402, the cathode subregion 204 may bedisabled, as shown by cross-hatching in FIG. 5. The one or more gaps 206that are around the disabled cathode subregion 502 will limit thepropagation of the anode material and arrest the chemical reaction 406from expanding into adjacent cathode subregions 204. Furthermore, theempty space 408 essentially creates an open circuit between the anodecurrent collector 310 and the disabled cathode subregion 502. Thus,since the cathode subregions 204 are essentially connected in parallel,the empty space 408 reduces the likelihood of healthy cathode subregions204 from discharging through the unhealthy cathode subregion 502, i.e.,the empty space 408 disconnects the void 402 from the remainder of theoperational electrochemical cell 200.

Referring to FIG. 6, a side view of an electrochemical cell having asubdivided cathode layer is shown in accordance with an embodiment. Inan embodiment, the cathode layer 304 includes separate cathodesubregions 204 separated by one or more gaps 206 that are filledentirely by a single dielectric, e.g., a gas such as an inert gas, or avacuum. For instance, an electrochemical cell 200 may be fabricatedhaving essentially flat thin layers that include, the anode layer 202,the electrolyte layer 302, the cathode layer 304, the barrier film layer306, and the cathode current collector 308. An ablation laser may thenbe used to laser scribe the one or more gaps 206 through the anode layer202, the electrolyte layer 302, and the cathode layer 304.Alternatively, the one or more gaps 206 may be formed in one or more ofthe anode layer 202, the electrolyte layer 302, and the cathode layer304 using masking techniques to control the areas of material depositionduring fabrication of the electrochemical cell 200. A thin layer ofmaterial may be removed from barrier film layer 506 as well, e.g., usinga laser ablation process, such that adjacent cathode subregions 204 arefully separated across gaps 206. As a result, several cathode subregions204 separated by one or more gaps 206 may be formed. Similarly, theelectrolyte layer 302 and the anode layer 202 may have respectivesubregions formed therein, separated by the one or more gaps 206. Thatis, rather than having a continuous layer structure as described abovewith respect to FIG. 3, anode layer 202 and/or electrolyte layer 302 maybe patterned to have a discontinuous layer structure with severalsubregions formed therein. The discontinuous layer structure may beplanar. That is, the subregions of the anode layer 202 and/orelectrolyte layer 302 may be essentially coplanar such that sidewalls ofthe several subregions of each layer face each other across the one ormore gaps 206 and respective upward/facing surfaces of the severalsubregions lie within a common transverse plane. Thus, theelectrochemical cell 200 may include several cell subregions 602physically separated from each other by the one or more gaps 206. Moreparticularly, each cell subregion 602 may include a stack of cathode,electrolyte, and anode subregions. Furthermore, an anode currentcollector 310 may be placed over the anode subregions to electricallyconnect each and all of the cell subregions 602 so as to form a singlecell. In an embodiment, the anode current collector 310 has a continuouslayer structure, e.g., a single sheet or film structure. Thus, anodesubregions may be electrically connected to each other through thecontinuous layer structure of the anode current collector 310. In anembodiment, the combined projected surface area of the cell subregions602 may be at least 80% of the total projected surface area of theelectrochemical cell 200 within the electrochemical cell perimeter 208,i.e., the patterned cathode utilization area may be at least 80%.

The electrolyte layer 302 in a cell subregion 602 may develop a void 402during manufacture or use. In such case, the anode layer 202 in thedefective cell subregion 602 may leak through the void 402 into anunderlying cathode subregion 204 in the defective cell subregion 602. Asdescribed above, the anode leak 404 may persist until the anode layer202 over the void 402 is reduced to a point that an empty space 408 iscreated between the void 402 and the anode current collector 310. Theempty space 408 may provide an electrical open circuit to reduce thelikelihood of the discharge of surrounding cell subregions 602 throughthe defective cell subregion 602. Furthermore, since the cathodesubregion 204 of each cell subregion 602 are physically separated by oneor more gaps 206, the leaking anode layer 202 material may be arrestedwithin the defective cell subregion 602 and disallowed from propagatingto other cell subregions 602. Accordingly, the negative effects of ananode leak 404 may be limited to the disablement of a single cellsubregion 602.

Referring to FIG. 7, a plan view of an electrochemical cell having asubdivided cathode layer and an anode current collector tab is shown inaccordance with an embodiment. In an embodiment, the anode layer 202 ofthe electrochemical cell 200 may also be an anode current collector. Forexample, the anode layer 202 may be metallic lithium with sufficientconductivity to act as a current collector across the entire face of theelectrochemical cell 200. Thus, a separate anode current collector 310over the anode layer 202 may be unnecessary. Accordingly, the anodelayer 202 may be used to electrically connect the electrochemicallyactive portions of the electrochemical cell 200 with external productcircuitry. For example, the anode layer 202 may be lithium that isconductively connected with external product circuitry through aseparate anode current collector tab 702. The anode layer 202 mayconduct electricity between electrochemically active regions ofelectrochemical cell 200 and the anode current collector tab 702. Theanode current collector tab 702 may, for example, be located in a cornerof the electrochemical cell 200. A region over which the anode currentcollector tab 702 is coupled with the anode layer 202 may not have acathode subregion 204, and thus, may be thinner than a portion of theelectrochemical cell 200 that includes a cathode subregion 204. Moreparticularly, in an embodiment, the thinner corner may be formed bylaser ablating or shadow masking the corner during formation of thecathode layer 304. Subsequently, the electrolyte layer 302 and the anodelayer 202 may be deposited over the thinner corner. As a result, theanode current collector tab 702 may be an electrically conductive metalfoil having a thickness equal to the thickness of the cathode subregions204 without adding to an overall height of the electrochemical cell 200.Thus, incorporating an anode current collector tab 702 in a corner ofthe electrochemical cell 200 rather than placing an anode currentcollector 310 over the entire anode layer 202 may result in higher totalenergy densities of fully packaged electrochemical cells 200 and/orelectrochemical devices incorporating electrochemical cells 200.Furthermore, the anode current collector tab 702 that is electricallyconnected to the anode layer 202 may be made thicker and more robust toimprove the reliability of electrical connections to external circuitry.

Referring to FIG. 8A, a cross-sectional view of an electrochemicaldevice having a defect in an electrolyte layer over a subdivided cathodelayer is shown in accordance with an embodiment. In an embodiment, anelectrochemical device 800 includes a first electrochemical cell 802stacked on a second electrochemical cell 804 such that respective anodelayers 202 of the electrochemical cells are adjacent to or in contactwith one another. The respective anode layers 202 may have continuouslayer structures, e.g., continuous sheet or film structures, that covercathode subregions 204 and extend into the one or more gaps 206 betweenadjacent cathode subregions 204. Furthermore, as described above, aregion of one or more of the stacked electrochemical cells, such as acorner region, may not include a cathode subregion. Thus, a tabinsertion space 806 between respective anode layers 202 may allow forinsertion of the anode current collector tab 702. The continuous layerstructures of the anode layers 202 may separate the tab insertion space806 from respective cathode current collectors 308 of the firstelectrochemical cell 802 and the second electrochemical cell 804. Thus,the anode current collector tab 702 may be sandwiched between the anodelayers 202 and electrically connected to the anode layers 202 within thetab insertion space 806 without contacting cathode current collectors308. Anode current collector tab 702 may be bonded to anode layers 202using, e.g., conductive pressure sensitive adhesive. As described above,a defect such as the void 402 may occur in an electrolyte layer 302,allowing for an anode leak 404 of the anode layer 202 material into thecathode subregion 204.

Referring to FIG. 8B, a cross-sectional view of an electrochemicaldevice having a defect in an electrolyte layer over a subdivided cathodelayer is shown in accordance with an embodiment. In an embodiment, sincethe respective anode layers 202 are in contact adjacent to the void 402,the anode leak 404 may include material from anode layers 202 of boththe first electrochemical cell 802 and the second electrochemical cell804 propagating through the void 402 to the affected cathode subregion204. As described above in relation to an electrochemical cell 200, thechemical reaction 406 in the cathode subregion 204 may persist until theempty space 408 is formed over the void 402. That is, the anode leak maystop after the anode material between electrolyte layers of theelectrochemical cells is drained. Accordingly, the electrochemicaldevice 800 having stacked electrochemical cells with subdivided cathodelayers may limit defects to individual cathode subregions 204 thatbecome physically and electrically isolated from other portions of theelectrochemical device 800. As such, a defective area may have littleimpact on the device performance, e.g., capacity, energy, power,resistance, cycle life, and yields and overall performance of theelectrochemical device 800 may be improved.

Referring to FIG. 9, a cross-sectional view of an electrochemical devicehaving an intermediate layer between subdivided cathode layers is shownin accordance with an embodiment. In an embodiment, the propagation ofanode layer 202 material when a void 402 occurs may be limited furtherby incorporating an intermediate layer 902 between respective anodelayers 202 of the stacked electrochemical cells in the electrochemicaldevice 800. For example, the intermediate layer 902 may include anelectrically conductive anode current collector between the anode layers202 that electrically connects the cathode subregions 204 of theelectrochemical device 800, but reduces the likelihood of anode layer202 material of a second electrochemical cell 804 from propagatingthrough a void 402 in an electrolyte layer 302 of the firstelectrochemical cell 802. Thus, when the void 402 forms, anode layer 202material from the first electrochemical cell 802 may propagate throughthe void 402 to cause chemical reactions in the cathode subregion 204until an empty space is formed between the intermediate layer 902 andthe void 402, thereby creating an open circuit and isolating the cathodesubregion 204 from the remainder of the electrochemical device 800.Although the anode current collector tab 702 is illustrated in FIG. 9,in an embodiment, intermediate layer 902 may be an anode currentcollector 310 that extends outside and away from electrochemical device800 for connection with external product circuitry. Thus, the anodecurrent collector tab 702 may be omitted in an embodiment in which it isa redundant with the intermediate layer 902.

In an alternative embodiment, the intermediate layer 902 may include aninsulating layer between the anode layers 202 of the stackedelectrochemical cells. For example, the insulating layer 902 may be athin film of insulating material that is inert to lithium. Examples ofsuch material include pressure sensitive adhesives, such as acrylics, aswell as other insulating materials such as polyimide, etc. Theinsulating layer may be one or both of electrically insulating orionically insulating, and may be made from materials having either ofthose properties.

Referring to FIG. 10, a plan view of an electrochemical cell having asubdivided anode layer is shown in accordance with an embodiment. Anelectrochemical cell 200 may include an anode layer 202 over a cathodelayer. Furthermore, the anode layer 202 may be subdivided into one ormore anode subregions 1002 spaced across the electrochemical cell 200above the cathode layer and the electrolyte layer. More particularly,the anode subregions 1002 may be separated from each other by one ormore gaps 206. For example, one or more gaps 206 may surround each anodesubregion 1002 to physically isolate the anode subregion 1002 fromneighboring anode subregions 1002.

In an embodiment, the anode layer 202 may include a grid pattern, inwhich each anode subregion 1002 includes a rectangular surface area andis separated from adjacent anode subregions 1002 by one or more lineargaps 206 traversing the electrochemical cell 200. After anode layermaterial is deposited over the electrolyte layer, laser scribing may beused to remove the anode layer material to form one or more gaps 206between anode subregions 1002. Alternatively, shadow masking may be usedto form anode subregions 1002 separated by masked regions that becomethe unfilled gaps 206. However, other anode layer 202 patterns may beused. For example, the one or more gaps 206 may be laser scribed in anyshape to form anode subregions 1002 that are, e.g., polygonal, conicsections, elliptical, etc. The remaining anode material of the anodesubregions 1002 essentially form islands of a patterned anode layer 202.Anode subregions 1002 may have a same or different shape as compared toother anode subregions 1002 in the anode layer 202.

Regardless of the shape of the anode subregions 1002, the anode layer202 may include a total projected surface area when viewed from abovewithin an electrochemical cell perimeter 208 that includes a combinedprojected surface area of each anode subregion 1002 and a combinedprojected surface area of the one or more gaps 206 between the anodesubregions 1002. For example, each anode subregion 1002 may have aprojected area of a square profile with equal sides and each gap 206 mayhave equal widths. Thus, a total projected surface area of the anodelayer 202 within an electrochemical cell perimeter 208 may include allof the projected square anode subregion surface areas as well as theprojected surface area within the uniform gaps 206. In an embodiment, apatterned anode area utilization, i.e., a ratio of the combinedindividual anode subregion surface areas to the total surface area ofthe anode layer 202, may be less than 30%. For example, the patternedanode area utilization may be less than 25%. In an embodiment, a gridpattern has square anode subregions 1002 with sides of 10 micronseparated by one or more 10 micron gaps 206. Thus, the patterned anodearea utilization may be expected to be 25%. Widening the one or moregaps 206 or shrinking the anode subregions 1002 can decrease thepatterned anode area utilization.

Referring to FIG. 11, a cross-sectional view, taken about line C-C ofFIG. 10, of an electrochemical cell having a subdivided anode layer isshown in accordance with an embodiment. In an embodiment, theelectrochemical cell 200 may include the electrolyte layer 302 betweenthe anode layer 202, having anode subregions 1002 and one or more gaps206, and the cathode layer 304. As described above, the one or more gaps206 in the anode layer 202 may define a space between the portions ofthe anode layer 202 that contain anode material such as lithium, i.e., aspace between anode subregions 1002. Gaps 206 may be formed by removinganode material and optionally a thin layer of electrolyte materialusing, e.g., a laser ablation process. Thus, the anode subregions 1002may be fully separated by intervening gaps 206. In an embodiment, thegaps 206 between the anode subregions 1002 of the anode layer 202 arefilled entirely by a single dielectric 312, e.g., a dielectric gas suchas an inert gas, or a vacuum. Furthermore, the barrier film layer 306may be between the cathode layer 304 and the cathode current collector308. In an embodiment, the electrochemical cell 200 may include theelectrically conductive anode current collector 310 placed in electricalcontact with the anode layer 202. The anode current collector 310 mayinclude a metal foil that makes mechanical and electrical contact withall of the anode subregions 1002 of the anode layer 202. In anembodiment, the various layers of electrochemical cell 200 may includematerials and dimensions similar to those described above with respectto the electrochemical cell 200 having a patterned cathode layer 304.

Referring to FIG. 12, a cross-sectional view, taken about line C-C ofFIG. 10, of an electrochemical cell having a defect in an electrolytelayer under a subdivided anode layer is shown in accordance with anembodiment. In an embodiment, the electrolyte layer 302 may include adefect, such as a void 402. As described above, the void 402 canintroduce a path for an electrical leak between the anode layer 202 andthe cathode layer 304. However, as compared to an electrochemical cell200 having a uniform, i.e., non-patterned anode layer 202 acrosselectrochemical cell 200, the electrochemical cell 200 having anodesubregions 1002 occupying only a fraction of the total projected surfacearea of the anode layer is less likely to have the void 402 aligned withan anode subregion 1002. More particularly, the void 402 may be threetimes more likely to be aligned with the one or more gaps 206 when thecombined projected surface areas of the anode subregions 1002 is only25% of a total projected surface of the anode layer 202. Thus, as aresult of the patterned anode layer 202, the likelihood of batteryfailure via internal short circuit between the anode subregions 1002 andthe cathode layer 304 may be reduced in proportion to the patternedanode area utilization.

Referring to FIG. 13A, a cross-sectional view, taken about line C-C ofFIG. 10, of an electrochemical cell having a defect in an electrolytelayer under a subdivided anode layer is shown in accordance with anembodiment. In an embodiment, the void 402 may occur in the electrolytelayer 302 between an anode subregion 1002 and the underlying cathodelayer 304. Thus, the void 402 can introduce a path for an electricalleak between the anode layer 202 and the cathode layer 304. That is, ananode leak 404 may occur as the anode layer material creeps into thecathode layer 304 through the void 402. As the anode material interactswith the cathode material, chemical reactions 406 may propagate throughthe cathode layer 304 to create unwanted chemical products. Furthermore,electron discharge from neighboring anode subregions 1002 may follow apathway 1302 through the anode current collector 310 into the anodesubregion 1002 adjacent to the void 402, and then onward through thevoid 402 into the cathode layer 304. Accordingly, the void 402 mayresult in self-discharge of the anode layer 202 that could eventuallydischarge the entire electrochemical cell 200.

Referring to FIG. 13B, a cross-sectional view, taken about line C-C ofFIG. 10, of an electrochemical cell having a defect in an electrolytelayer under a subdivided anode layer is shown in accordance with anembodiment. As the anode leak persists, chemical reactions in thecathode layer 304 may continue and be accompanied by concomitantdisappearance of the anode subregion 1002 adjacent to the void 402. Thatis, anode layer material may physically leak through the void 402 untilthere is no longer anode material above void 402. Accordingly, an emptyspace 408 may be created above the void 402, e.g., between theelectrolyte layer 302 and the anode current collector 310. The emptyspace 408 may create an electrical open circuit between the electrolytelayer 302 and the anode current collector 310. Thus, the anode leak mayeventually cease, and the chemical reaction and electrical leakage inthe cathode layer 304 may stop. In an embodiment, the anode leak mayresult in a degraded region 1304 of the cathode layer 304, but a largerhealthy region of the cathode layer 304 may be unaffected by the anodeleak. Thus, a patterned anode layer may mitigate the impact of anelectrolyte layer defect on overall performance of the electrochemicalcell 200.

Referring to FIG. 14, a side view of an electrochemical device having ananode current collector between subdivided anode layers is shown inaccordance with an embodiment. In an embodiment, an electrochemicaldevice 800 may be formed from several electrochemical cells 200 havingpatterned anode layers as described with respect to FIG. 10. Moreparticularly, several electrochemical cells 200 may be stacked withrespective anode subregions 1002 facing one another. Some of the anodesubregions 1002 in the anode layers may be directly across from theanode current collector 310 from one another, i.e., may appearoverlapping when viewed from above (i.e., when viewed verticallydownward along the plane of the drawing sheet). The anode currentcollector 310 may have a continuous layer structure, e.g., a continuoussheet or film structure. Thus, the anode subregions 1002 of respectivestacked electrochemical cells 200 may be electrically connected to eachother through the continuous layer structure of the anode currentcollector 310. That is, the anode subregions 1002 of a firstelectrochemical cell 200 of electrochemical device 800 may beelectrically connected with each other, as well as electricallyconnected with anode subregions 1002 of a second electrochemical cell200 of electrochemical device 800, through the continuous layerstructure of the anode current collector 310. Furthermore, the anodecurrent collector 310 having a continuous layer structure may be betweenrespective cathode layers 304 of the stacked electrochemical cells 200of electrochemical device 800, thereby physically separating theelectrochemical cells 200.

In an embodiment, one or more of the stacked electrochemical cells 200forming electrochemical device 800 may include a cathode currentcollector 308 electrically connected to a cathode layer 304. Forexample, a first cathode current collector 308 may be electricallyconnected to a cathode layer 304 of a first electrochemical cell 200 ofelectrochemical device 800 and a second cathode current collector 308may be electrically connected to a cathode layer 304 of a secondelectrochemical cell 200 of electrochemical device 800. Both the cathodelayer 304 and the cathode current collector 308 may have continuouslayer structures, e.g., continuous sheet or film structures.

In an embodiment, the electrochemical device 800 may include a void 402in one of the electrolyte layers 302 that causes an anode leak 404 toreduce the size of a respective anode subregion 1002 adjacent to thevoid 402. Accordingly, the anode subregion 1002 will eventually shrinkto fill space laterally away from void 402 (not under void 402), asindicated by the dotted lines in FIG. 14, to result in an empty spacebetween the void 402 and the anode current collector 310. Thus, thedegraded region 1304 of the underlying cathode layer 304 may be limitedby the size of the anode subregion 1002 adjacent to the void 402. Assuch, an electrochemical device having patterned anode layers may limitthe impact that an electrolyte void has on overall performance of thedevice.

Referring to FIG. 15, a plan view of an electrochemical cell having asubdivided anode layer over a subdivided cathode layer is shown inaccordance with an embodiment. In an embodiment, electrochemical cell200 may be subdivided into several cell subunits 1500, and each cellsubunit may include at least two anode subregions 1002 disposed over acathode subregion 204. That is, the anode layer 202 may be subdividedinto one or more anode subregions 1002 spaced across the electrochemicalcell 200 above a cathode layer 304 that is also subdivided into one ormore cathode subregions 204. For example, as shown in FIG. 15, eachcathode subregion 204 may provide a base to support four anodesubregions 1002, although this is illustrated by way of example and notlimitation. More particularly, the cathode layer 304 may be patterned toinclude at least two cathode subregions 204, and two or more of theanode subregions 1002 may be disposed over one of the cathode subregions204 represented with hidden lines. In each of the cathode layer 304 andthe anode layer 202, one or more gaps may surround each patternedisland. For example, one or more gaps 1502A may separate anodesubregions 1002 from neighboring anode subregions 1002, and one or moregaps 1502B may separate cathode subregions 602 from a neighboringcathode subregions 602. Accordingly, the gaps 1502B may also extend intothe page between cell subunits 1500 to separate the cell subunits. Asdescribed above, the gaps 1502A and 1502B may be at least partiallyfilled by a dielectric 312, e.g., a dielectric gas.

Referring to FIG. 16, a cross-sectional view, taken about line D-D ofFIG. 15, of an electrochemical cell having a subdivided anode layer overa subdivided cathode layer is shown in accordance with an embodiment. Inan embodiment, the electrochemical cell 200 may include the electrolytelayer 302 between the anode layer 202, having anode subregions 1002 andone or more gaps 1502A, and the cathode layer 304, having cathodesubregions 204 and one or more gaps 1502B. As described above, the oneor more gaps 1502A in the anode layer 202 may define a space between theanode subregions 1002. Anode subregions 1002 may contain anode materialsuch as lithium. In an embodiment, the one or more gaps 1502A are filledentirely by a single dielectric 312, e.g., a dielectric gas such as aninert gas, or a vacuum. Also as described above, the one or more gaps1502B in the cathode layer 304 may define a space between the cathodesubregions 204 (and also separate anode subregions 1002 located onadjacent cathode subregions 204). The cathode subregions may containcathode material. In an embodiment, the one or more gaps 1502B arefilled entirely by a single dielectric 312, e.g., a dielectric gas suchas an inert gas, or a vacuum. In an embodiment, the electrochemical cell200 may include the electrically conductive anode current collector 310placed in electrical contact with anode subregions 1002. The anodecurrent collector 310 may include a metal foil that makes mechanical andelectrical contact with all of the anode subregions 1002 in theelectrochemical cell 200. Furthermore, the electrochemical cell 200 mayinclude an electrically conductive cathode current collector 308 placedin electrical connection with the cathode subregions 204. That is, thecathode subregions 204 may electrically connect to a common, or shared,cathode current collector 308. The various layers of electrochemicalcell 200 may include materials and dimensions similar to those describedabove.

In an embodiment, the anode layer 202 and the cathode layer 304 may eachinclude a grid pattern, as described above. In an embodiment, the anodelayer 202, the cathode layer 304, and the electrolyte layer 302 may beformed over, e.g., cathode current collector 310, in uniform layers. Thelayers may then be selectively laser scribed to create one or more gaps1502B separating cathode subregions 204 (and also separating anodesubregions 1002 located on adjacent cathode subregions 204) and one ormore gaps 1502A separating anode subregions 1002 on top of one or moreof cathode subregions 204. More particularly, laser scribing may removematerial to create essentially a set of cathode islands with a set ofanode islands over one of the cathode islands. Other methods, includingshadow masking may be used to form the structure shown in FIG. 16.

Referring to FIG. 17, a flowchart illustrating a method for isolating acathode layer from an anode leak is shown in accordance with anembodiment. At operation 1702, during production of an electrochemicalcell 200 or assembly of an electrochemical device 800, such as asolid-state battery, a void 402 in an electrolyte layer 302 may bedetected. Detection of the void 402 may occur at various times duringthe manufacturing process, including before or after deposition of theanode layer 202 over the electrolyte layer 302. At operation 1704, oncethe void 402 is detected, various operations may be employed to ensurethat the cathode layer 304 in a finished electrochemical cell 200 willbe isolated from the anode layer 202 across the electrolyte layer 302.For example, the void 402 may be filled or the anode layer material maybe removed from over the void 402 to reduce the likelihood of an anodeleak 404. Embodiments of methods for detecting a void 402 and isolatingthe cathode layer 304 will be described further below.

Referring to FIG. 18, a side view of an electrochemical cell during adefect detection operation is shown in accordance with an embodiment.Detection of the void 402 at operation 1702 may include detectionperformed by optical, electrical, thermal, and other testing methodsthat are known for finding material voids. For example, anelectrochemical cell 200 may be viewed under microscopy to detect thevoid 402. In an embodiment, the void 402 in electrolyte layer 302 causesa depression 1802 in an anode subregion 1002 of the anode layer 202, asthe anode layer material creeps into the void 402. The depression 1802may be visible as a discoloration or as a defective topology, such as asinkhole on a top surface of an anode subregion 1002. Thus, the void 402may be identified by optical methods.

In an embodiment, the void 402 may be detected with electrical methods.For example, the anode layer 202 may include several anode subregions1002 over a top surface of the electrochemical cell 200. Depending onthe integrity of the electrolyte layer 302 beneath the anode subregions1002, the voltage at the anode subregions 1002 may vary. For example, avoltage probe may be placed on the rightmost anode subregion 1002 shownin FIG. 18 to measure a first voltage measurement and the center anodesubregion 1002 may be probed to measure a second voltage measurement. Inan embodiment, given that the void 402 may create an electrical shortbetween the center anode subregion 1002 and the cathode layer 304, thefirst voltage measurement may be markedly higher than the second voltagemeasurement. It may therefore be inferred through voltage readings of apatterned anode layer which anode subregions 1002 are adjacent to voids402. Thus, in addition to increasing yield and mitigating the impact ofdefects on cell performance, an electrochemical cell 200 having apatterned anode layer 202 may also facilitate identification of defectsduring manufacturing, so that they may be dealt with prior to productpackaging. This may increase yields and product performance evenfurther.

Additional methods of detecting voids 402 may be used. For example,electrical methods of detection may also include measuring current flowor resistivity across the electrochemical cell 200 to infer a void 402location. Thermal methods of detection include monitoring surfacetemperatures of electrochemical cell 200 while applying a current toinfer void 402 locations through the identification of localized hotspots. Other methods include electromagnetic wave deflection,absorption, reflection, raman scattering, etc., that can be used todetect pinholes in materials, i.e., the void 402 in electrolyte layer302. Depending upon the stage of manufacturing at which the void 402 isdetected, various methods may be used to mitigate the impact of the void402 by isolating the cathode layer 304 under the void 402. Inparticular, modifications may be made to ensure that in the finalelectrochemical cell 200 assembly, the cathode layer 304 under the void402 is either not in electrical communication with the anode layer 202,or is isolated from surrounding cathode layer 304 areas to mitigate theimpact that an anode leak 404 may have on electrochemical cell function.

Referring to FIG. 19, a side view of a precursor cell having a defect inan electrolyte layer is shown in accordance with an embodiment. Aprecursor cell 1900 may include the electrolyte layer 302, the cathodelayer 304, the barrier film layer 306, and the cathode current collector308. Thus, in an embodiment, the precursor cell 1900 represents a stateof manufacturing prior to deposition of the anode layer 202 over theelectrolyte layer 302. At this stage, a void 402 may be detected in theelectrolyte layer 302 using any of the methods described above, or otherdetection methods. Accordingly, a repair technique may be employed thatwill reduce the likelihood of an anode leak 404 through the void 402after the anode layer 202 is deposited over the electrolyte layer 302.

Referring to FIG. 20, a side view of an electrochemical cell having abackfilled electrolyte layer is shown in accordance with an embodiment.In an embodiment, the void 402 detected in the precursor cell 1900 maybe filled with a filler 2002. For example, the void 402 may be ablated,drilled, ground, etc., to form a bore 2004 through the electrolyte layer302. The bore 2004 may enlarge the void in electrolyte layer 302, makingit easier to insert a filler material. Furthermore, although the bore2004 may be controlled to stop at an upper surface of the cathode layer304, in an embodiment, the bore 2004 may extend into the cathode layer304. After creating bore 2004, a filler material may be backfilled intothe bore 2004. Thus, when the anode layer 202 is deposited in asubsequent operation, the cathode layer 304 may be electrically isolatedfrom the anode layer 202 across filler 2002. Accordingly, the filler2002 may include a variety of materials that may be inert to lithium,and which may be electrically insulating. The choice of materials mayinclude adhesive materials that can be injected into the bore 2004 andthen allowed to cure under, e.g., time, heat, and/or ultravioletradiation.

Referring to FIG. 21, a side view of an electrochemical cell having adefect in an electrolyte layer is shown in accordance with anembodiment. In an embodiment, the void 402 in the electrolyte layer 302may be detected after deposition of the anode layer 202. For example,one of the detection methods described above may be used to detect thevoid 402 prior to placing an anode current collector 310 over the anodelayer 202. In an embodiment, the anode layer may be patterned tofacilitate detection using voltage probing, as described above.Accordingly, a repair technique may be employed that isolates thecathode layer 304 from an anode leak 404 through the void 402.

Referring to FIG. 22A, a side view of an electrochemical cell having acathode layer isolated from an anode leak is shown in accordance with anembodiment. In an embodiment, the anode layer 202 over the void 402 maybe removed such that the void 402 does not extend from the anode layer202 to the cathode layer 304. That is, the anode material is removedover a first end of the void 402, is not present above void 402, andthus cannot leak through the void. Accordingly, an anode leak 404through the void 402 may not be established, and thus, the impact ofvoid 402 on electrochemical cell 200 performance may be mitigated.Removal of the anode layer 202 may include forming a blind hole 2202over the void 402. An inner dimension of the blind hole 2202 may be atleast as large as the void 402 diameter and the bottom of the blind hole2202 may terminate at or below an upper surface of the electrolyte layer302. Accordingly, the repaired electrochemical cell 200 may have noanode layer 202 material adjacent to the void 402, and the risk of ananode leak 404 occurring may therefore be reduced.

Referring to FIG. 22B, a side view of an electrochemical cell having acathode layer isolated from an anode leak is shown in accordance with anembodiment. In an embodiment, the anode layer 202 and the void 402 maybe removed to isolate the cathode layer 304 from the anode layer 202.More particularly, a blind hole 2202 may be formed through the anodelayer 202 and the electrolyte layer 302 to remove the void 402. Asidewall 2204 of the blind hole 2202 may be contiguous such that eachlayer along the sidewall 2204 is electrically isolated and essentiallycontinuous with one another, e.g., as in having a tapered sidewall 2204.That is, although the sidewalls 2004 of the anode layer 202 and theelectrolyte layer 302 may be essentially continuous with one another,the anode layer 202 may be sufficiently isolated from the cathode layer304 to reduce the likelihood of anode layer 202 material fromelectrically shorting with the cathode layer 304. Accordingly, therepaired electrochemical cell 200 may reduce the risk of an anode leak404 occurring in an assembled solid-state battery.

Referring to FIG. 22C, a side view of an electrochemical cell having acathode layer isolated from an anode leak is shown in accordance with anembodiment. In an embodiment, rather than removing the anode layer 202adjacent to the void 402, a portion of the cathode layer 304 may beisolated from the rest of the cathode layer 304 so that if an anode leak404 occurs, the degraded region will be limited to a small fraction ofthe cathode layer 304. Thus, the impact on electrochemical cellperformance may be reduced. In an embodiment, a channel 2206 may beformed around the void 402 to isolate a first cathode portion 2208 froma second cathode portion 2210. The channel 2206 may be annular having aninner wall that includes the first cathode portion 2208 sidewall and anouter wall that includes the second cathode portion 2210 sidewall.Furthermore, the channel 2206 may extend from an upper surface of theelectrochemical cell 200 or precursor cell 1900 to the barrier filmlayer 306 (and may even extend below the top surface of barrier filmlayer 206 supporting cathode layer 304). Thus, the channel 2206 maycreate a discontinuity to physically isolate the cathode portions fromeach other. In an embodiment, the channel 2206 may be backfilled with,e.g., a dielectric filler, to further isolate the cathode portionsphysically, electrically, or ionically. Although an anode leak 404 mayform between the anode layer 202 and the first cathode portion 2208, thefirst cathode portion 2208 volume may be small so as to cause the entireportion to chemically react and to then cease to support furtherpropagation of the chemical reaction to nearby areas of the cathodelayer 304. Accordingly, the repaired electrochemical cell 200 may reducethe impact of an anode leak 404 on electrochemical cell 200 performance.

The various repair modifications described above with respect toisolating the cathode layer 304 may be made using a variety offabrication technologies. For example, a bore 2004, a blind hole 2202,or a channel 2206 may be formed through one or more layers of theelectrochemical cell 200 using, e.g., laser machining techniques such aslaser ablation, abrasive jet machining, etching, etc. Some of theseprocesses, such as laser ablation, can remove portions of materiallayers, such as a thin top layer from barrier film layer 306, withoutmelting and cutting through the entire material thickness, as istypically the case with conventional laser cutting processes.Furthermore, modifications that involve the addition of materials, suchas backfilling the bore 2004 with the filler 2002, may be performedusing material application techniques such as coating, infusion,deposition, etc. Accordingly, the impact of electrolyte layer defects onproduct cost and performance may be mitigated by detecting and repairingthe defects.

The present invention also provides the following itemized embodiments:

1. An electrochemical cell, comprising: an electrolyte layer between ananode layer and a cathode layer, wherein the electrolyte layer includesa hole at least partially filled by a filler, and wherein the fillerseparates the anode layer from the cathode layer.

2. An electrochemical cell, comprising: an electrolyte layer between ananode layer and a cathode layer, wherein the electrolyte layer includesa void extending from a first end to the cathode layer, and wherein theanode layer includes a hole over the void such that the hole separatesthe void from the anode layer.

3. An electrochemical cell, comprising: an electrolyte layer between ananode layer and a cathode layer, wherein the electrolyte layer includesa void; and a channel extending through the electrolyte layer and thecathode layer around the void, such that a first region of the cathodelayer is separated from a second region of the cathode layer by thechannel.

4. A method, comprising: detecting a void in an electrolyte layer,wherein the void extends from a first end to a cathode layer of anelectrochemical cell; and isolating the cathode layer from the firstend.

5. The method of item 4, wherein the electrolyte layer is between thecathode layer and an anode layer, and wherein detecting the voidincludes measuring an electrical voltage at one or more anode subregionsof the anode layer.

6. The method of item 4, wherein isolating the cathode layer includesfilling the void with a filler to separate the cathode layer from thefirst end.

7. The method of item 4 further comprising depositing an anode layerover the electrolyte layer such that the void extends from the anodelayer to the cathode layer, and wherein isolating the cathode layerincludes removing the anode layer over the void such that the void doesnot extend from the anode layer to the cathode layer.

8. The method of item 4 further comprising depositing an anode layerover the electrolyte layer such that the void extends from the anodelayer to a first region of the cathode layer, and wherein isolating thecathode layer includes forming a channel around the void through theelectrolyte layer and the cathode layer, such that the first region ofthe cathode layer is separated from a second region of the cathode layerby the channel.

In the foregoing specification, the invention has been described withreference to specific exemplary embodiments thereof. It will be evidentthat various modifications may be made thereto without departing fromthe broader spirit and scope of the invention as set forth in thefollowing claims. The specification and drawings are, accordingly, to beregarded in an illustrative sense rather than a restrictive sense.

What is claimed is:
 1. An electrochemical cell, comprising: a cathodecurrent collector having a continuous layer structure; a cathode layerhaving a plurality of cathode subregions electrically connected to eachother through the continuous layer structure of the cathode currentcollector, wherein the plurality of cathode subregions are separated bya gap, and wherein the gap is at least partially filled by a dielectricgas; and an electrolyte layer between the plurality of cathodesubregions and an anode layer.
 2. The electrochemical cell of claim 1,wherein a combined projected surface area of the cathode subregions isat least 80 percent of a total projected surface area of the cathodelayer.
 3. The electrochemical cell of claim 1 further comprising ananode current collector electrically connected to the anode layer. 4.The electrochemical cell of claim 3, wherein the plurality of cathodesubregions include respective sidewalls separated by the gap, whereinthe anode layer includes a continuous layer structure covering thesidewalls, and wherein the gap separates a portion of the anode layerdisposed between the sidewalls from the anode current collector.
 5. Anelectrochemical device, comprising: a first electrochemical cellincluding a first cathode layer having a plurality of first cathodesubregions separated by a gap and electrically connected to a firstcathode current collector, and a first anode layer over the plurality offirst cathode subregions; and a second electrochemical cell including asecond cathode layer having a plurality of second cathode subregionsseparated by the gap and electrically connected to a second cathodecurrent collector, and a second anode layer over the plurality of secondcathode subregions; wherein the first electrochemical cell is stacked onthe second electrochemical cell such that the first anode layer iscoupled with the second anode layer and a tab insertion space isdisposed between the first cathode current collector and the secondcathode current collector.
 6. The electrochemical cell of claim 5,wherein the plurality of first cathode subregions include respectivesidewalls separated by the gap, the first anode layer includes acontinuous layer structure covering the sidewalls, and the gap is formedbetween opposing portions of the first anode layer covering opposingsidewalls.
 7. The electrochemical cell of claim 5, wherein the pluralityof second cathode subregions include respective sidewalls separated bythe gap, the second anode layer includes a continuous layer structurecovering the sidewalls, and the gap is formed between opposing portionsof the second anode layer covering opposing sidewalls.
 8. Theelectrochemical device of claim 5 further comprising an anode currentcollector tab disposed in the tab insertion space.
 9. Theelectrochemical device of claim 8, wherein the anode layers includerespective continuous layer structures separating the tab insertionspace from respective cathode current collectors, and wherein the anodecurrent collector tab is electrically connected to the anode layers. 10.The electrochemical cell of claim 5, wherein a combined projectedsurface area of the first cathode subregions is at least 80 percent of atotal projected surface area of the first cathode layer, and wherein acombined projected surface area of the second cathode subregions is atleast 80percent of a total projected surface area of the second cathodelayer.
 11. The electrochemical cell of claim 5 further comprising aninsulating layer between the first cathode layer and the second cathodelayer and physically connected to the anode layers, wherein theinsulating layer is inert to lithium.
 12. The electrochemical cell ofclaim 11, wherein the plurality of first cathode subregions includerespective sidewalls separated by the gap, the first anode layerincludes a continuous layer structure covering the sidewalls, and thegap is defined by the first anode layer and the insulating layer. 13.The electrochemical cell of claim 11, wherein the plurality of secondcathode subregions include respective sidewalls separated by the gap,the second anode layer includes a continuous layer structure coveringthe sidewalls, and the gap is defined by the second anode layer and theinsulating layer.
 14. An electrochemical cell, comprising: an anodecurrent collector having a continuous layer structure; an anode layerhaving a continuous structure; a cathode current collector having acontinuous layer structure; and a cathode layer having a plurality ofcathode subregions electrically connected to each other through thecontinuous layer structure of the cathode current collector, wherein theplurality of cathode subregions are separated by a gap, wherein theplurality of cathode subregions include respective sidewalls separatedby the gap, wherein the continuous structure of the anode layer coversthe sidewalls, and wherein the gap separates a portion of the anodelayer disposed between the sidewalls from the anode current collector.15. The electrochemical cell of claim 14 further comprising anelectrolyte layer between the plurality of cathode subregions and theanode layer.
 16. The electrochemical cell of claim 14, wherein acombined projected surface area of the cathode subregions is at least 80percent of a total projected surface area of the cathode layer.
 17. Theelectrochemical cell of claim 14, wherein the gap is at least partiallyfilled with a dielectric gas.